JP5004510B2 - Gas cooker ignition device - Google Patents

Description

  The present invention relates to an ignition device provided for igniting a burner in a gas cooker such as a stove or a grill that burns and burns a burner.

For example, as a grill ignition device, a so-called push-type cock (closed) is known as disclosed in Patent Document 1. In this ignition device, a gas supply passage is provided, and an ignition operation shaft having an ignition knob fixed to the front end is provided in a flashing device provided with a magnet solenoid valve for opening and closing the gas supply passage. The rear end of the ignition operation shaft is connected to a cock provided in the flashing device. Further, an ignition micro switch (ignition switch) is provided in front of the flashing device, and a cam is integrally provided on the ignition operation shaft.
Therefore, when the ignition knob is pushed during the ignition operation, the ignition operation shaft moves backward to forcibly open the magnet solenoid valve. When the ignition knob is rotated as it is, the cock integrated with the ignition operation shaft rotates to supply fuel gas from the gas supply path to the burner, and the cam turns on the ignition switch. Then, the controller as the control means that detects the ON state of the ignition switch operates the igniter to ignite the burner, and energizes the magnet electromagnetic valve to hold it open.
On the other hand, during the fire extinguishing operation, when the ignition knob is rotated to the fire extinguishing side, the cam turns off the ignition switch. Therefore, the controller stops energizing the magnet solenoid valve, closes the magnet solenoid valve, and shuts off the gas supply.

Japanese Patent Laid-Open No. 2001-4131

  As described above, in the ignition device, the ignition switch is not turned on unless the pressed ignition operation shaft is rotated by a predetermined angle. Therefore, if the pushing force is weakened when the ignition switch is turned on and the ignition operation shaft is returned, even if the magnet solenoid valve is energized, the valve is not held open, resulting in poor ignition.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an ignition device for a gas cooker that is of such a push-turn type, can reliably hold the magnet electromagnetic valve open at the time of ignition, and has excellent ignition operation reliability. It is what.

In order to achieve the above object, according to the first aspect of the present invention , the cam is integrally provided on the ignition operation shaft, while the ignition switch is operated on the rotation trajectory of the cam when the ignition operation shaft is rotated at the forward movement position. comprising an ignition switch to pieces is located, at the time of ignition operation, with the pushing operation of the ignition operating shaft from the advanced position, the ignition switch is turned oN by the cam moves away from the operating piece, at the time of fire extinguishing operation, the advanced position with the rotation operation to the extinguishing position side of the ignition operating shaft, Ru der those wherein the ignition switch is on so that the OFF by the cam contacts the operating piece.

According to the first aspect of the present invention, during the ignition operation, the ignition switch is turned on by the pushing operation of the ignition operating shaft and the magnet solenoid valve is energized. Even if this is insufficient, the magnet solenoid valve is reliably held open. Therefore, ignition failure is less likely to occur, and a highly reliable ignition device can be obtained.
Further, the use of the cam makes it easy to link the ignition operation shaft and the ignition switch.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is an explanatory side view showing an example of an ignition device provided in a grill as a gas cooker. The ignition device 1 includes a frame 2 fixed to a not-shown body of the grill, and a rear side of the frame 2 (see FIG. 1). 1 (A) left side) and a flashing device 3 extending in the front-rear direction. A gas supply path 4 is formed in the flasher 3 in the front-rear direction, provided on the rear side of the flasher 3 and supplied with fuel gas from a gas pipe, and on the burner side provided on the front side The gas outlets 6 are connected to the gas outlets 6 respectively. At the rear end of the gas supply path 4, a magnet electromagnetic valve 7 that opens and closes the gas supply path 4 near the gas inlet 5 is disposed, while in the gas supply path 4, the gas supply path 4 closes at the gas outlet 6. A closing member 9 that adjusts the opening degree and a spindle 8 that includes radial pins 8 a and 8 a that engage with the closing member 9 and rotate the closing member 9 are provided. The spindle 8 is urged to a forward position by a coil spring 10 provided in the gas supply path 4, and at this forward position, the magnet electromagnetic valve 7 is urged by the urging of the valve body as shown in FIG. The gas supply path 4 is closed. When the spindle 8 is pushed backward and moved backward, the rear end of the spindle 8 pushes the valve body of the magnet electromagnetic valve 7 to forcibly open the valve.

  The frame 2 has a two-ply rear plate 11 to which the flasher 3 is fixed, and a U-shaped front plate 12 screwed in parallel with the rear plate 11 by connecting plates 13 and 13 provided on the upper and lower sides. Between the rear plate 11 and the front plate 12, an ignition operation shaft 14 having a two-sided cross section is held so as to be movable back and forth in the axial direction and rotatable, and a rear end penetrating the rear plate 11 is provided. The flasher 3 is connected to the spindle 8 coaxially. The ignition operation shaft 14 is provided with a locking plate 15 near the rear plate 11 and a fan-shaped needle cam 16 on the front plate 12 so as to be integrally rotatable. The ignition operation shaft 14 is urged to a forward position where the stopper portion 18 provided at the rear of the rear plate 11 comes into contact with the rear plate 11 by the main coil spring 17 packaged in the above. This advance position corresponds to the advance position of the spindle 8.

  In addition, a restriction plate 19 is externally mounted on the ignition operation shaft 14 so as to be integrally rotatable within the flasher 3 and movable back and forth in the axial direction, and is urged by a coil spring 20 to a forward position where it contacts the stopper portion 18. . At this forward position, the rotation of the ignition operation shaft 14 at the forward position is restricted by engaging with a stopper (not shown) provided in the flasher 3. When the ignition operation shaft 14 is pushed in (retracted) against the bias of the main coil spring 17, the restricting plate 19 is retracted and the interference with the stopper is released, and together with the spindle 8 in the left direction in FIG. It can be rotated. An ignition knob 21 is fixed to the front end of the ignition operation shaft 14 in front of the front plate 12.

  Further, a switch cam 22 serving as a cam of the present invention is externally provided in front of the needle cam 16 on the ignition operation shaft 14. As shown in FIG. 4B, the switch cam 22 is configured to position the fan-shaped cam portion 23 on the opposite side of the fan-shaped cam portion of the needle cam 16, and the rear surface of the cam portion 23 (the surface on the pushing side). ) Is a contact surface with an operating piece 34 of an igniter switch 32 to be described later. However, as for the contact surface, as viewed in FIG. 4B, most of the ignition operation shaft 14 on the right side in the rotation direction is the first contact surface 24, and the left end portion in the rotation direction of the ignition operation shaft 14 is the first contact surface. The second contact surface 25 is located in front of the second contact surface 25, and the first contact surface 24 and the second contact surface 25 are continuously formed on the inclined surface 26. Further, on the outer peripheral side of the inclined surface 26, a corner 27 that protrudes from an operating piece 38 of an ignition switch 37, which will be described later, protrudes.

  The switch cam 22 is inserted into the fitting hole 28 that is fitted to the ignition operation shaft 14 so that the switch cam 22 can rotate by a predetermined angle (here, 35 °) in both forward and reverse directions with respect to the two surface widths of the ignition operation shaft 14. Plays 29 and 29 corresponding to the angles are provided point-symmetrically. However, one end of the main coil spring 17 is locked to the locking piece 30 erected forward from the locking plate 15, and the other end is locked to the cam portion 23 of the switch cam 22 by being twisted. Since the switch cam 22 is also a torsion spring that urges the switch cam 22 in the clockwise direction, the switch cam 22 rotates integrally with the ignition operation shaft 14 in a state in which no play is generated in the clockwise direction. In the fire extinguishing position of the ignition operation shaft 14 shown in FIG. 1, the rotation is restricted by a restriction piece 31 bent backward from the front plate 12 so that play is generated only when the ignition operation shaft 14 is rotated counterclockwise. .

  Reference numeral 32 denotes a micro switch for igniter operation (hereinafter referred to as “igniter switch”). On the fixed piece 33 bent forward from the side end of the rear plate 11, a chevron-shaped contact portion 35 is formed with the operation piece 34 in the front side. The switch cam 22 is mounted in a slanting vertical direction so as to be located behind the second contact surface 25 of the switch cam 22 in the fire extinguishing position. Above the igniter switch 32, an ignition microswitch (hereinafter referred to as “ignition switch”) 37 is moved forward and backward on a fixed piece 36 bent forward from the side end of the rear plate 11. A mountain-shaped contact portion 39 is attached in an obliquely vertical direction so that the operation piece 38 is pushed in by interfering with the corner portion 27 of the switch cam 22 at the fire extinguishing position.

On the other hand, as shown in FIGS. 1B and 2, a manifold 40 is attached to the side surface of the frame 2 opposite to the igniter switch 32 attachment side. The manifold 40 is incorporated in a bypass pipe (not shown) that bypasses the flasher 3 from the gas pipe and is connected to the burner side, and opens and closes a bypass flow path by a needle valve 41 provided therein. A pin 42 is attached orthogonally to the projecting end portion of the manifold 40 and one end of a coil spring 43 is externally mounted. The other end of the coil spring 43 is engaged with one end 45 of a U-shaped guide metal fitting 44 screwed to the side surface of the frame 2, and the needle valve 41 is pushed into the manifold 40 (in the bypass flow path). It is energized to the closed side. A slit 47 into which one end of the pin 42 is loosely inserted is formed at the other end 46 of the guide fitting 44 to guide the movement of the needle valve 41 in the axial direction and to restrict the rotation.
Further, the other end of the pin 42 is engaged with the free end side of an L-shaped swinging plate 48 that is pivotally mounted on the rear side of the needle valve 41 so that the end of the pin 42 can be rotated to the frame 2 side. The pushing position of the needle valve 41 is regulated. A lever 50 is bent at the free end of the swing plate 48 and protrudes into the frame 2 so that it can interfere with the needle cam 16.

  In FIG. 1B, reference numeral 51 denotes a spring plate having one end fixed on the front side of the front plate 12 and provided with a pin 52 penetrating the front plate 12 and protruding into the frame 2 at the other end. Pins 52 are formed in notches and through-holes (not shown) formed concentrically on the periphery of the click plate 53 provided integrally with the ignition operation shaft 14 in front of 22 at a fire extinguishing position, a high fire position, and a low fire position, which will be described later. So that a click feeling during rotation operation of the ignition operation shaft 14 can be obtained.

The point-extinguishing operation of the ignition device 1 configured as described above will be described with reference to explanatory views showing the front and rear positions and the rotation angle of the ignition operation shaft 14 of FIG.
First, in the fire extinguishing position of the ignition operation shaft 14 (position a shown in FIG. 3), the ignition operation shaft 14 is in the forward movement position shown in FIG. 1, and the switch cam 22 has the second contact surface 25 as described above. Located in front of the contact portion 35 of the igniter switch 32, the corner portion 27 pushes in the operating piece 38 of the ignition switch 37 (the ignition switch 37 at this time is OFF). Further, the cam portion of the needle cam 16 pushes the lever 50, and the swing plate 48 is rotated in the direction in which the needle valve 41 is pulled out via the pin 42. Therefore, the bypass channel of the manifold 40 is opened.

  When the ignition knob 21 is pushed in from here, as shown in FIG. 4, the ignition operation shaft 14 moves backward to forcibly open the magnet electromagnetic valve 7 via the spindle 8 (position b in FIG. 3) and at the same time. The corner portion 27 of the retracted switch cam 22 moves away from the operating piece 38 of the ignition switch 37 and turns on the ignition switch 37 (position a ′). Therefore, a controller (not shown) serving as a control means energizes the magnet electromagnetic valve 7 to keep it open and supply fuel gas to the burner. At this time, the second contact surface 25 of the switch cam 22 stays close to the contact portion 35 of the igniter switch 32 and does not push in the operating piece 34.

  Next, when the ignition knob 21 is pushed in and rotated counterclockwise, as shown in FIG. 5, the ignition operation shaft 14 first rotates 35 ° which is the amount of play 29 (position c), and then the switch cam 22 is ignited. It rotates counterclockwise together with the shaft 14. As shown in FIG. 6, the inclined surface 26 of the switch cam 22 abuts on the contact portion 35 of the igniter switch 32 at a position d where the switch cam 22 rotates 20 ° (the ignition operation shaft 14 is 55 °) counterclockwise. The operating piece 34 is pushed in by riding 35 on the first contact surface 24. Therefore, the controller that has turned on the igniter switch 32 and obtained this ON signal operates the igniter for a predetermined time to ignite the burner. Since the ON state of the ignition switch 37 does not change, energization to the magnet solenoid valve 7 is maintained.

  If the ignition knob 21 is rotated 5 ° as it is (position e), the restricting plate 19 abuts against a stopper (not shown) in the flasher 3 and further rotation is restricted, so that the pushing of the ignition knob 21 is released here. Then, as shown in FIG. 7, the ignition operation shaft 14 returns to the forward position by the biasing of the coil spring 10 (position f). At the same time, the switch cam 22 moves forward and separates from the operating piece 34 of the igniter switch 32 (position e ′), so that the igniter switch 32 is turned off. At this time, the gas supply path 4 is fully opened by the closing member 9 rotated together with the spindle 8, so that the burner burns with a strong fire. Even in this high fire position, the position of the swing plate 48 by the needle cam 16 does not change, so the bypass flow path remains open.

When the ignition knob 21 is further rotated counterclockwise by 40 ° from this high fire position as shown in FIG. 8, the closing member 9 is throttled, the gas supply path 4 is half-opened, and the burner burns with a low fire (position g). In this low heat position, as shown in FIG. 9B, the needle cam 16 moves away from the lever 50 and releases the restriction of pushing the needle valve 41 by the swing plate 48. Therefore, as shown in FIG. 43 is pushed into the manifold 40 to close the bypass flow path. At this time, the igniter switch 32 is OFF and the ignition switch 37 is ON.
When the burner is misfired at the high fire position and the low fire position, the controller that has monitored the burner combustion with the thermoelectromotive force of the thermocouple detects this and stops energization of the magnet solenoid valve 7. 7 closes and the gas supply path 4 is closed.

Then, when the ignition knob 21 is rotated to the right when the burner is extinguished, the switch cam 22 that eliminates play 29 in the corresponding direction by biasing the right rotation rotates integrally with the ignition operation shaft 14, as shown in FIG. 10. The switch cam 22 reaches the fire extinguishing position earlier than the ignition operating shaft 14 returns to the fire extinguishing position, and the corner 27 is brought into contact with the contact part 39 of the ignition switch 37 to push the operating piece 38 (position). h). Therefore, the ignition switch 37 is turned off and the controller that detects this stops the energization of the magnet solenoid valve 7, closes the gas supply path 4 on the gas inlet 5 side, and extinguishes the burner. When the ignition knob 21 is further rotated clockwise, after the switch cam 22 abuts against the regulating piece 31, only the ignition operation shaft 14 rotates by the play 29, and when the fire extinguishing position (position a) is reached, the closing member 9 The gas supply path 4 is closed on the outlet 6 side.
When the ignition knob 21 is rotated clockwise, the needle cam 16 presses the lever 50 and the swing plate 48 is pulled toward the needle valve 41 as shown in FIG. Rock. Therefore, the needle valve 41 protrudes from the manifold 40 against the bias of the coil spring 43 and opens the bypass flow path. For this reason, even if the rotation operation of the ignition knob 21 is quickly performed between the positions g and h, the supply of the fuel gas to the burner through the bypass pipe is maintained, and the unexpected disappearance does not occur.

As described above, according to the ignition device 1 of the above embodiment, the ignition switch 37 is turned on in cooperation with the ignition operation shaft 14 side to be pushed in during the ignition operation, and is rotated to the fire extinguishing position side during the fire extinguishing operation. Since the ignition switch 37 is turned off in conjunction with the ignition operation shaft 14 side, when the ignition operation is performed, the ignition switch 37 is turned on by pushing the ignition operation shaft 14 and the magnet solenoid valve 7 is energized. The magnet electromagnetic valve 7 is reliably held open even if the amount of pushing in the subsequent rotation operation of the ignition operation shaft 14 is insufficient. Therefore, ignition failure is less likely to occur, and a highly reliable ignition device 1 can be obtained.
In particular, here, the switch cam 22 is provided integrally with the ignition operation shaft 14, and the switch cam 22 turns on the ignition switch 37 during the ignition operation, while the switch cam 22 turns off the ignition switch 37 during the fire extinguishing operation. By employing the switch cam 22, the linkage between the ignition operation shaft 14 and the ignition switch 37 can be easily realized.

In the above embodiment, a switch cam is integrally provided on the ignition operation shaft and linked to the ignition switch. Instead of such a cam, a protrusion, a rib, or the like is provided on the outer surface of the ignition operation shaft. May be linked to the ignition switch during the ignition operation.
On the other hand, in the case of using a cam, it is not always necessary to set play between the ignition operation shaft as in the above embodiment, and even if the timing of the ignition switch OFF during the fire extinguishing operation is delayed depending on the type and performance of the cooker. If it is good, the cams can be coupled together in the rotational direction.
In the above embodiment, the two switches of the ignition switch and the igniter switch are turned on / off at different timings, but the magnet electromagnetic valve adsorption current and the igniter are turned on / off at the same timing with only one ignition switch. It is also possible to turn it off. In this case, the igniter may be turned off after detecting ignition with a thermocouple (in the case of non-ignition, it is turned off after a lapse of a certain time).

It is explanatory drawing of an ignition device, (A) shows the left side surface, (B) shows the front (ignition knob is abbreviate | omitted), respectively. It is right side explanatory drawing of an ignition device. It is explanatory drawing which shows the front-back position and rotation angle of the ignition operation axis | shaft at the time of point extinction. It is explanatory drawing of the ignition device of the state which pushed in the ignition knob, (A) shows the position of the switch cam and needle cam seen from the left side surface, and (B) from the front, respectively. It is explanatory drawing of the ignition device in the state where the ignition operation shaft is rotated by the amount of play, (A) shows the positions of the switch cam and the needle cam as viewed from the left side, and (B) from the front, respectively. It is explanatory drawing of the ignition device of the state where the igniter switch was turned on, (A) shows the position of the switch cam and needle cam which were seen from the left side, and (B) from the front, respectively. It is explanatory drawing of the ignition device of the state which cancelled | released pushing of the ignition knob, (A) shows the position of the switch cam and needle cam which looked at the left side surface, and (B) from the front, respectively. It is explanatory drawing of the ignition device in a low fire position, (A) shows the position of the switch cam and needle cam which were seen from the left side surface, and (B) from the front, respectively. It is right side explanatory drawing of the ignition device in a low fire position. It is explanatory drawing of the ignition device of the state which rotated the ignition knob to the fire extinguishing side, (A) shows the position of the switch cam and needle cam seen from the left side surface, and (B) from the front, respectively.

Explanation of symbols

1..Ignition device, 2..Frame, 3..Flasher, 4..Gas supply path, 7..Magnet solenoid valve, 8..Spindle, 9..Closer, 11..Rear plate, 12 .. -Front plate, 14-Ignition operation shaft, 16-Needle cam, 17-Main coil spring, 21-Ignition knob, 22-Switch cam, 24-First contact surface, 25-Second contact Contact surface, 26 .. inclined surface, 27 .. corner, 28 .. fitting hole, 29 .. play, 32 .. igniter switch, 37 .. ignition switch, 41.

Claims (1)

An ignition operation shaft with an ignition knob fixed to the front end for forcibly opening a magnet solenoid valve provided in the gas supply path by pushing into the flashing device, and rotation operation of the ignition operation shaft after burner ignition A closing member capable of adjusting the opening of the gas supply path, an ignition switch that is turned ON / OFF in conjunction with the operation of the ignition operation shaft, and energizing the magnet solenoid valve by the ON operation of the ignition switch; An ignition device for a gas cooker comprising a control means for stopping energization of the magnet solenoid valve by an OFF operation of an ignition switch,
While providing a cam integrally with the ignition operation shaft, the ignition switch includes the ignition switch so that the operation piece of the ignition switch is positioned on the rotation trajectory of the cam when the ignition operation shaft is rotated in the forward position.
When the ignition operation is performed, the ignition switch is turned on when the cam is moved away from the operating piece in accordance with the pushing operation of the ignition operation shaft from the forward position, and during the fire extinguishing operation, the ignition operation shaft is extinguished at the forward position. An ignition device for a gas cooker, wherein the ignition switch is turned off when the cam comes into contact with the operating piece in accordance with a rotation operation to a position side.

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